WO2021103579A1 - Thin film material surface acoustic wave device with gs layered electrode, preparation method therefor and use thereof - Google Patents

Abstract

Disclosed are a thin film material surface acoustic wave device with a GS layered electrode, a preparation method therefor and the use thereof. The device sequentially comprises a substrate, a first layer of interdigital transducer, a silica thin film, a piezoelectric thin film and a second layer of interdigital transducer from bottom to top. The preparation method therefor comprises the following steps: 1) using a photoetching technique and an electron beam evaporation method to prepare the first layer of interdigital transducer on the surface of the substrate; 2) growing a silica thin film on the first layer of interdigital transducer and substrate by using a magnetron sputtering method; 3) leveling the surface of the silica thin film, and then growing a piezoelectric thin film on the surface thereof by using the magnetron sputtering method; and 4) preparing the second layer of interdigital transducer on the piezoelectric thin film by using the method in step 1), and aligning the second layer of interdigital transducer with the first layer of interdigital transducer according to settings, and exposing the electrode PAD area of the first layer of interdigital transducer by using the photoetching technique so as to obtain the device. The present invention has a higher frequency and a higher temperature stability, and also has a stronger integration performance.

Description

A thin film material surface acoustic wave device with GS layered electrodes and its preparation method and application Technical field

The invention relates to the field of electronic information materials, in particular to a surface acoustic wave device and a preparation method and application thereof, and in particular to a thin-film material surface acoustic wave device with GS layered electrodes, and a preparation method and application thereof.

Background technique

Surface acoustic waves are mechanical waves generated and propagated on the surface of piezoelectric materials. Due to its high sensitivity, small size, and low cost, surface acoustic waves have been widely used in electronic devices such as resonators, filters, sensors, and convolutions. Especially in the field of mobile communications, surface acoustic wave filters play a vital role.

In the RF front-end module, the performance of the RF filter is very important. Surface acoustic wave filters and bulk acoustic wave filters are currently the two most mainstream radio frequency filters. Surface acoustic wave filters are simple to prepare, but they are difficult to apply to high frequency bands; while bulk acoustic wave filters are often used in high frequency bands, but their preparation process is complicated. The 5G era is approaching, and people have put forward higher requirements for RF filters. People's increasing demand for communication frequency bands has made spectrum resources increasingly tight, and higher frequency bands have to be used. Since the surface acoustic wave filter has the advantage of low cost, the preparation of a high-performance high-frequency surface acoustic wave filter will greatly promote the development of the 5G era.

At present, there are mainly three methods to increase the frequency of surface acoustic wave devices, namely, reducing the period of the sound wave, increasing the speed of sound, and adopting an acoustic wave mode with higher frequency resonance. Since the adoption of these methods will be restricted by the technological level and material system, as well as by the quality of the acoustic wave and the production cost, in recent years, everyone has encountered a bottleneck on how to increase the frequency of surface acoustic wave devices. A new method to increase the frequency of the device. In addition, high temperature stability has always been the goal of high-performance filter research; and high integration performance is also a development direction for future filters.

Invention Disclosure

The object of the present invention is to provide a thin-film material surface acoustic wave device with GS layered electrodes. The device has higher frequency, higher temperature stability, and at the same time has stronger integration performance.

The invention provides a surface acoustic wave device, which includes a substrate, a first-layer interdigital transducer, a silicon dioxide film, a piezoelectric film, and a second-layer interdigital transducer in sequence from bottom to top.

In the present invention, the substrate can be made of a material known in the art, which is not strictly limited; specifically, the substrate is selected from at least one of Si substrate, SiC substrate and sapphire substrate; The main function of the film is to support. At the same time, due to the difference in performance, different substrates will have a certain impact on the performance of the device; in specific embodiments, it can be a high-resistance (100) Si substrate with a thickness of 500μm or a 6H with a thickness of 500μm. -SiC substrate.

In the above-mentioned surface acoustic wave device, the internal structure of the first-layer interdigital transducer and the second-layer interdigital transducer are the same, and both include a metal bottom layer and a metal main body layer; the metal bottom layer is arranged at The lower part of the metal body layer.

In the above-mentioned surface acoustic wave device, the metal forming the metal underlayer includes at least one of Ti, Ni, Zr, and Cr;

The metal forming the metal body layer includes at least one of Al, Cu, Pt, and Mo;

The thickness of the metal primer layer is 1-50nm; specifically, it can be 5nm, 10nm, 5nm-10nm, 5nm-30nm or 2nm-30nm;

The thickness of the metal body layer is 20 to 200 nm; specifically, it can be 30 nm, 55 nm, 80 nm, 160 nm, 55 nm to 100 nm, 50 to 150 nm, 30 to 80 nm or 50 to 160 nm.

In the above-mentioned surface acoustic wave device, the line width of the interdigital transducer of the first layer and the interdigital transducer of the second layer are both 100nm～5μm, and specifically may be 0.5μm, 0.25μm, 0.25μm～0.5μm , 0.20μm～1μm or 0.20μm～3μm, denoted as d; the distance between adjacent fingers of the interdigital transducer in each layer is 100nm～15μm, specifically 0.5μm, 0.25μm, 270nm, 350nm, 270nm～350nm , 0.25μm～1μm, 0.20μm～3μm, 270nm～10μm or 3μm～15μm, denoted as g2.

In the above-mentioned surface acoustic wave device, the first-layer interdigital transducer is embedded in the bottom of the silicon dioxide film;

In the relative position in the horizontal direction, the interdigital transducers of the first-layer interdigital transducer and the second-layer interdigital transducer are arranged in a staggered distribution. Specifically, the distance between the interdigital transducer of the first layer of interdigital transducer and the adjacent two interdigital transducers of the second layer of interdigital transducer is equal, and this distance is denoted as g1. The specific embodiment may be 10nm, 50nm or 10nm～50nm.

In the present invention, the line width of the two-layer interdigital transducers is the same, and the distance between adjacent interdigital transducers is also the same, and has the following numerical relationship: g1+d+g1=g2. Through the adjustment of these three dimensions, the frequency of the device can be adjusted.

In the above-mentioned device, the function of the silicon dioxide film is to fill the gap of the interdigital transducer of the first layer, reduce holes and regain a flat upper surface, at the same time realize temperature compensation, and improve the temperature stability of the device.

In the present invention, the thickness of the silicon dioxide film may be 20nm-40μm, specifically may be 1μm, 150nm, 180nm, 150nm-180nm or 100nm-20μm, which can be specifically determined according to actual needs.

In the above-mentioned surface acoustic wave device, one of the first-layer interdigital transducer and the second-layer interdigital transducer is grounded, and the other is connected to a signal.

In the above-mentioned surface acoustic wave device, the material of the piezoelectric film is selected from at least one of zinc oxide, aluminum nitride, doped zinc oxide, and doped aluminum nitride.

The thickness of the piezoelectric film may be 20nm-40μm, specifically 120nm, 156nm, 1μm, 120nm-156nm or 100nm-20μm, which can be specifically determined according to actual needs.

In the above-mentioned surface acoustic wave device, the doping element in the doped zinc oxide is at least one of V, Cr and Fe;

The doping amount of the doping element in the doped zinc oxide may be 0.3-5%, and specifically may be 1.96%.

The doping element in the doped aluminum nitride is Sc;

The doping amount of the doping element in the doped aluminum nitride can be 0.1-70%, specifically 43%.

In the present invention, the doping amount is an atomic percentage of the doped element atom content to the total metal element atom content of the doping material.

The present invention also provides a method for preparing the above-mentioned surface acoustic wave device, including the following steps: 1) preparing the first-layer interdigital transducer on the surface of the substrate by using photolithography technology and an electron beam evaporation method;

2) Using a magnetron sputtering method to grow the silicon dioxide film on the first-layer interdigital transducer and the substrate;

3) Use chemical mechanical polishing and/or the etching method to smooth the surface of the silicon dioxide film, and then use the magnetron sputtering method to grow the piezoelectric film on the surface;

4) Use the method in step 1) to prepare a second layer of interdigital transducer on the piezoelectric film, and align it with the first layer of interdigital transducer according to the settings, and use the photolithography The technique exposes the electrode PAD area of the interdigital transducer of the first layer to obtain the surface acoustic wave device.

In the above-mentioned preparation method, before step 1), a step of cleaning the surface of the substrate is further included.

In the preparation method of the present invention, the magnetron sputtering method, electron beam evaporation method, photolithography technology, chemical mechanical polishing, photolithography technology and alignment method are all commonly used methods in the field, and their conditions are also Conventional feasibility conditions.

The surface acoustic wave device of the present invention is applied to the preparation of a high-frequency device with temperature compensation performance and/or a surface acoustic wave device that is convenient for the integration of a radio frequency front end. Specifically, single-ended surface acoustic wave resonators can be prepared or used in the preparation of 5G surface acoustic wave devices that are convenient for radio frequency front-end integration.

Description of the drawings

Fig. 1 is a schematic cross-sectional view of the device of the present invention (the actual device has a large number of interdigital transducers, and only part of the interdigital transducer is cut out in the figure).

Figure 2 is a schematic cross-sectional view of the interdigital transducer in the device of the present invention. The figure includes a metal primer layer and a metal main body layer.

FIG. 3 is a schematic cross-sectional view of a smaller area of the device of the present invention, and several key dimensions are marked to facilitate the description of the content of the invention and the embodiments.

FIG. 4 is a simulated vibration mode diagram of the surface acoustic wave resonator in Embodiment 1 of the present invention, and not all the substrates are shown in the figure.

Fig. 5 is a simulated admittance curve of the surface acoustic wave resonator in Example 1 of the present invention.

FIG. 6 is a simulated vibration mode diagram of the surface acoustic wave resonator in Embodiment 2 of the present invention, and not all the substrates are shown in the figure.

Fig. 7 is a simulated admittance curve of a surface acoustic wave resonator in Example 2 of the present invention.

The labels in the figure are as follows:

1 substrate; 2 first layer of interdigital transducer; 3 silicon dioxide film; 4 piezoelectric film; 5 second layer of interdigital transducer; 6 interdigital transducer layer; 7 interdigital transducer The metal body layer in the transducer.

The best way to implement the invention

The experimental methods in the following examples, unless otherwise specified, are all conventional methods

Example 1,

The structure shown in Figure 1 was prepared, and a high-resistance (100) Si substrate with a thickness of 500 μm was used, followed by ultrasonic cleaning with acetone, alcohol, deionized water, and alcohol, and then dried with a nitrogen gun.

The first-layer interdigital transducer is prepared by photolithography and electron beam evaporation method. As shown in Fig. 3, the dimension line width d is 250nm, and the size g1 (is the interdigital and first-layer interdigital transducer of the first layer) The distance between adjacent fingers of the two-layer interdigital transducer, and all the distances are equal) is taken as 50nm, and g2 (the distance between adjacent interdigitals of the interdigital transducer in each layer) is taken as 350nm. The material of the interdigital transducer is 5nm Ti metal base layer and 55nm Al metal main layer. The specific preparation process is as follows: firstly, the photolithography process is carried out. The specific steps of photolithography include surface cleaning and drying, primer coating, spin coating of photoresist, soft baking, exposure, post baking, developing, and hard baking. After the photolithography is completed, the interdigital transducer pattern on the sample has been formed. Then put the sample into the electron beam evaporator for coating. The specific experimental conditions of the electron beam evaporation method are as follows: the background vacuum is better than 9×10 ^-9 torr, and the Ti coating rate is

Al coating rate is

After the evaporation is completed, the sample is taken out from the evaporation machine and placed in acetone for peeling, thereby completing the preparation of the first-layer interdigital transducer.

Using magnetron sputtering to grow 180nm silicon dioxide, the specific experimental conditions are as follows: background vacuum is better than 7×10 ^-5 Pa, silicon target reactive sputtering, DC power supply, power supply 1000W, Ar flow rate 18sccm, O ₂ Flow rate 12sccm, room temperature coating, coating pressure 0.5Pa, coating time 12min.

The surface of the silicon dioxide film is treated by chemical mechanical polishing technology.

The magnetron sputtering method is used to grow 120nm zinc oxide on the surface of the flat silicon dioxide film. The specific experimental conditions are as follows: background vacuum is better than 8×10 ^-5 Pa, Zn target reactive sputtering, radio frequency power supply, power supply 140W, Ar flow rate 18sccm, O ₂ flow rate 10sccm, coating temperature 350℃, coating pressure 0.8 Pa, coating time 15min.

The second-layer interdigital transducer is prepared by photolithography technology and electron beam evaporation method. The size and specific preparation process of the interdigital transducer have been described in the preparation of the first-layer interdigital transducer. When preparing the second-layer interdigital transducer, attention should be paid to alignment to ensure the realization of the structure in Figure 1.

The zinc oxide and silicon dioxide film above the electrode PAD area of the first interdigital transducer is etched by photolithography technology, so that it is exposed on the surface to facilitate the application of electrical signals. The device described in this example has been prepared.

If this embodiment is used to prepare a single-ended surface acoustic wave resonator, the simulation results are shown in Figs. 4 and 5. It can be seen from Figures 4 and 5 that the surface acoustic wave resonator can stably propagate high-order Rayleigh wave signals, and the signal is excellent. The resonant frequency of the resonator is 8.4091 GHz, the anti-resonant frequency is 8.4166 GHz, and the electromechanical coupling coefficient is 0.22%.

Example 2,

The structure shown in Figure 1 was prepared, and a 6H-SiC substrate with a thickness of 500 μm was used, which was ultrasonically cleaned with acetone, alcohol, deionized water, and alcohol in sequence, and then dried with a nitrogen gun.

The first-layer interdigital transducer is fabricated by photolithography and electron beam evaporation method, as shown in Fig. 3, the size d is 250 nm, the size g1 is 10 nm, and the size g2 is 270 nm. The material of the interdigital transducer is 5nm Ti metal bottom layer and 55nm Al metal main layer. The specific preparation process is as follows: firstly, the photolithography process is carried out. The specific steps of photolithography include surface cleaning and drying, primer coating, spin coating of photoresist, soft baking, exposure, post baking, developing, and hard baking. After the photolithography is completed, the interdigital transducer pattern on the sample has been formed. Then put the sample into the electron beam evaporator for coating. The specific experimental conditions of the electron beam evaporation method are as follows: the background vacuum is better than 9×10 ^-9 torr, and the Ti coating rate is

Al coating rate is

After the evaporation is completed, the sample is taken out from the evaporation machine and placed in acetone for peeling, thereby completing the preparation of the first-layer interdigital transducer.

Using magnetron sputtering method to grow 150nm silicon dioxide, the specific experimental conditions are as follows: background vacuum is better than 7×10 ^-5 Pa, silicon target reactive sputtering, DC power supply, power supply 1000W, Ar flow rate 18sccm, O ₂ Flow 12sccm, room temperature coating, coating pressure 0.5Pa, coating time 10min.

The surface of the silicon dioxide film is treated by chemical mechanical polishing technology.

The magnetron sputtering method is used to grow 156nm zinc oxide on the surface of the flat silicon dioxide film. The specific experimental conditions are as follows: background vacuum is better than 8×10 ^-5 Pa, Zn target reactive sputtering, radio frequency power supply, power supply 140W, Ar flow rate 18sccm, O ₂ flow rate 10sccm, coating temperature 350℃, coating pressure 0.8 Pa, the coating time is 19.5min.

The second-layer interdigital transducer is prepared by photolithography technology and electron beam evaporation method. The size and specific preparation process of the interdigital transducer have been described in the preparation of the first-layer interdigital transducer. When preparing the second-layer interdigital transducer, attention should be paid to alignment to ensure the realization of the structure in Figure 1.

The zinc oxide and silicon dioxide film above the electrode PAD area of the first interdigital transducer is etched by photolithography technology, so that it is exposed on the surface to facilitate the application of electrical signals. The device described in this example has been prepared.

If this embodiment is used to prepare a single-ended surface acoustic wave resonator, the simulation results are shown in Figs. 6 and 7. The surface acoustic wave resonator can stably propagate high-order Rayleigh wave signals, and the signal is good. The resonant frequency of the resonator is 9.7664 GHz, the anti-resonant frequency is 9.7837 GHz, and the electromechanical coupling coefficient is 0.44%.

Industrial application

1. The said surface acoustic wave device adopts the method of layering the ground terminal and the signal terminal of the interdigital transducer to further reduce the horizontal distance between the two signal terminal interdigits, thereby further reducing the distance on the basis of the prior art. The wavelength increases the frequency of the device.

2. The surface acoustic wave device of the present invention introduces a dense and flat silicon dioxide film on the interdigital transducer, which not only improves the temperature stability of the device, but also ensures the quality of the entire device.

3. The device of the present invention has no special requirements on the substrate, and both the silicon dioxide layer and the piezoelectric layer are prepared by thin film technology, so the device is convenient for the integration of the radio frequency front end.

4. The surface acoustic wave device of the present invention meets the higher requirements for radio frequency filters in the 5G era.

Claims (12)

1. A surface acoustic wave device includes a substrate, a first-layer interdigital transducer, a silicon dioxide film, a piezoelectric film, and a second-layer interdigital transducer in sequence from bottom to top.
2. The surface acoustic wave device according to claim 1, wherein the internal structure of the first-layer interdigital transducer and the second-layer interdigital transducer are the same, and both include a metal bottom layer and a metal body layer. ; The metal base layer is located at the lower part of the metal body layer.
3. The surface acoustic wave device according to claim 2, wherein the metal used for making the metal primer layer comprises at least one of Ti, Ni, Zr and Cr;

   The metal forming the metal body layer includes at least one of Al, Cu, Pt, and Mo;

   The thickness of the metal primer layer is 1-50nm;

   The thickness of the metal body layer is 20-200 nm.
4. The surface acoustic wave device according to claim 3, wherein the thickness of the metal primer layer is 2-30 nm;

   The thickness of the metal body layer is 50-150 nm.
5. The surface acoustic wave device according to claim 1 or 2, wherein the line widths of the interdigital transducers of the first layer and the interdigital transducers of the second layer are both 100nm～5μm, and the interdigital transducers of each layer The distance between adjacent interdigital fingers of the transducer is 100nm～15μm.
6. The surface acoustic wave device according to claim 5, wherein the line width of the interdigital transducer of the first layer and the interdigital transducer of the second layer are both 200nm-3μm, and the interdigital transducer in each layer The distance between adjacent interdigital fingers of the energy device is 270nm～10μm.
7. The surface acoustic wave device according to claim 1 or 2, wherein the first-layer interdigital transducer is embedded in the bottom of the silicon dioxide film;

   In the relative position in the horizontal direction, the interdigital transducers of the first-layer interdigital transducer and the second-layer interdigital transducer are arranged in a staggered distribution.
8. The surface acoustic wave device according to claim 1 or 2, wherein one of the first-layer interdigital transducer and the second-layer interdigital transducer is grounded, and the other is connected to a signal.
9. The surface acoustic wave device according to claim 1, wherein the material of the piezoelectric film is selected from at least one of zinc oxide, aluminum nitride, doped zinc oxide, and doped aluminum nitride.
10. The surface acoustic wave device according to claim 9, wherein the doping element in the doped zinc oxide is at least one of V, Cr and Fe;

    The doping amount of the doping element in the doped zinc oxide is 0.3-5%.

    The doping element in the doped aluminum nitride is Sc;

    The doping amount of the doping element in the doped aluminum nitride is 0.1-70%.
11. The method for preparing a surface acoustic wave device according to any one of claims 1-10, comprising the following steps: 1) Using photolithography technology and electron beam evaporation method to prepare the first layer fork on the surface of the substrate Refers to the transducer;

    2) Using a magnetron sputtering method to grow the silicon dioxide film on the first-layer interdigital transducer and the substrate;

    3) Use chemical mechanical polishing and/or etching to make the surface of the silicon dioxide film flat, and then use magnetron sputtering to grow the piezoelectric film on the surface;

    4) Use the method in step 1) to prepare a second layer of interdigital transducer on the piezoelectric film, and align it with the first layer of interdigital transducer according to the settings, and use photolithography technology to expose The electrode PAD area of the interdigital transducer of the first layer is the surface acoustic wave device.
12. The surface acoustic wave device of any one of claims 1-10 is used as a high-frequency and temperature-compensating device and/or used in the preparation of a surface acoustic wave device that facilitates the integration of a radio frequency front end.

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